BACKGROUNDTransplantation of livers obtained from donors after circulatory death is associated with an increased risk of nonanastomotic biliary strictures. Hypothermic oxygenated machine perfusion of livers may reduce the incidence of biliary complications, but data from prospective, controlled studies are limited.
Human whole-liver perfusion-decellularization is an emerging technique for producing bio-scaffolds for tissue engineering purposes. The native liver extracellular matrix (ECM) provides a superior microenvironment for hepatic cells in terms of adhesion, survival and function. However, current decellularization protocols show a high degree of variation in duration. More robust and effective protocols are required, before human decellularized liver ECM can be considered for tissue engineering applications. The aim of this study is to apply pressure-controlled perfusion and test the efficacy of two different detergents in porcine and human livers.To test this, porcine livers were decellularized using two different protocols; a triton-x-100 (Tx100)-only protocol (N = 3) and a protocol in which Tx100 was combined with SDS (N = 3) while maintaining constant pressure of 120 mm Hg. Human livers (N = 3) with different characteristics (age, weight and fat content) discarded for transplantation were decellularized using an adapted version of the Tx-100-only protocol. Decellularization efficacy was determined by histology and analysis of DNA and RNA content. Furthermore, the preservation of ECM components was assessed.After completing the perfusion cycles with detergents the porcine livers from both protocols were completely white and transparent in color. After additional washing steps with water and DNase, the livers were completely decellularized, as no DNA or cell remnants could be detected. The Tx100-only protocol retained 1.5 times more collagen and 2.5 times more sGAG than the livers decellularized with Tx100 + SDS. The Tx100-only protocol was subsequently adapted for decellularizing whole-organ human livers. The human livers decellularized with pressure-controlled perfusion became off-white in color and semi-transparent within 20 h. Livers decellularized without pressure-controlled perfusion took 64-96 h to completely decellularize, but did not become white or transparent. The addition of pressure-controlled flow did remove all cells and double stranded DNA, but did not damage the ultra-structure of the ECM as was analyzed by histology and scanning electron microscopy. In addition, collagens and sGAG were maintained with the decellularized ECM.In conclusion, we established effective, robust and fast decellularization protocols for both porcine and human livers. With this protocol the duration of decellularization for whole-organ human livers has been shortened considerably. The increased pressure and flow did not damage the ECM, as major ECM components remained intact.
Background. Abdominal normothermic regional perfusion (aNRP) for donation after circulatory death is an emerging organ preservation technique that might lead to increased organ utilization per donor by facilitating viability testing, improving transplant outcome by early reversal of ischemia, and decreasing the risk of unintentional surgical damage. The aim of the current review is to evaluate the recent literature on the added value of aNRP when compared to local standard perfusion technique. Methods. The Preferred Reporting Items for Systematic reviews and Meta-Analyses guideline for systematic reviews was used, and relevant literature databases were searched. Primary outcomes were organ utilization rate and patient and graft survival after 1 year. Secondary outcomes included delayed graft function, primary nonfunction, serum creatinine, and biliary complications. Results. A total of 24 articles were included in this review. The technique is unanimously reported to be feasible and safe, but the available studies are characterized by considerable heterogeneity and bias. Conclusions. Uniform reported outcome measures are needed to draw more definitive conclusions on transplant outcomes and organ utilization. A randomized controlled trial comparing aNRP with standard procurement technique in donation after circulatory death donors would be needed to show the added value of the procedure and determine its place among modern preservation techniques.
Biliary disorders can lead to life‐threatening disease and are also a challenging complication of liver transplantation. As there are limited treatment options, tissue engineered bile ducts could be employed to replace or repair damaged bile ducts. We explored how these constructs can be created by seeding hepatobiliary LGR5+ organoids onto tissue‐specific scaffold. For this, we decellularized discarded human extrahepatic bile ducts (EBD) that we recellularized with organoids of different origin, that is, liver biopsies, extrahepatic bile duct biopsies, and bile samples. Here, we demonstrate efficient decellularization of EBD tissue. Recellularization of the EBD extracellular matrix (ECM) with the organoids of extrahepatic origin (EBD tissue and bile derived organoids) showed more profound repopulation of the ductal ECM when compared with liver tissue (intrahepatic bile duct) derived organoids. The bile duct constructs that were repopulated with extrahepatic organoids expressed mature cholangiocyte‐markers and had increased electrical resistance, indicating restoration of the barrier function. Therefore, the organoids of extrahepatic sources are identified to be the optimal candidate for the development of personalized tissue engineered EBD constructs.
Female, 3 month old Yorkshire pigs (n=9, weight ~30kg) were sedated with an intra muscular injection of ketamine (Alfasan, Woerden, Netherlands) and midazolam (Actavis, Hafnarfjordur, Iceland). Throughout the procedure, the pigs were anesthetized using ketamine, midazolam, and sufentanil (Janssen-Cilag, Tilburg, Netherlands). After induction of anesthesia, tracheotomy was performed for intubation and mechanical ventilation. Midline laparotomy was performed, after which the hepatoduodenal ligament was dissected to identify the hepatic artery and portal vein. Before retrieval of the liver, the hepatic artery, portal vein and hepatic veins were clamped for 15 to 45 minutes using vascular type clamps, resulting in a total exclusion of blood flow through the liver, to induce warm ischemic liver injury, mimicking donor warm ischemia in DCD liver donors. After retrieval, the livers were cannulated at the portal vein and hepatic artery, cooled and flushed with 1L of ice-cold preservation fluid (Belzer
Acceptance of liver grafts from donations after circulatory death (DCD) largely remains a “black box,” particularly due to the unpredictability of the agonal phase. Abdominal normothermic regional perfusion (aNRP) can reverse ischemic injury early during the procurement procedure, and it simultaneously enables graft viability testing to unravel this black box. This review evaluates current protocols for liver viability assessment to decide upon acceptance or decline during aNRP. The Preferred Reporting Items for Systematic Reviews and Meta‐Analyses (PRISMA) guideline was used, and relevant literature databases were searched. The primary outcome consisted of criteria for liver graft viability assessment. Secondary outcomes included survival, primary nonfunction (PNF), early dysfunction, and biliary complications. A total of 14 articles were included in the analysis. In all protocols, a combination of criteria was used to assess suitability of the liver for transplantation. As many as 12 studies (86%) used macroscopic assessment, 12 studies (86%) used alanine transaminase (ALT) levels in perfusate, 9 studies (64%) used microscopic assessment, and 7 studies (50%) used lactate levels as assessment criteria. The organ utilization rate (OUR) was 16% for uncontrolled donation after circulatory death (uDCD) and 64% for controlled donation after circulatory death (cDCD). The most used acceptation criterion in uDCD is ALT level (31%), while in cDCD macroscopic aspect (48%) is most used. Regarding postoperative complications, PNF occurred in 13% (6%–25%) of uDCD livers and 3% (2%–4%) of cDCD livers. In uDCD, the 1‐year graft and patient survival rates were 75% (66%–82%) and 82% (75%–88%). In cDCD, the 1‐year graft and patient survival rates were 91% (89%–93%) and 93% (91%–94%), respectively. In conclusion, the currently used assessment criteria consist of macroscopic aspect and transaminase levels. The acceptance criteria should be tailored according to donor type to prevent an unacceptable PNF rate in uDCD and to increase the relatively modest OUR in cDCD.
No single reliable parameter exists to assess liver graft function of extended criteria donors during ex-vivo normothermic machine perfusion (NMP). The liver maximum capacity (LiMAx) test is a clinically validated cytochromal breath test, measuring liver function based on 13CO2 production. As an innovative concept, we aimed to integrate the LiMAx breath test with NMP to assess organ function. Eleven human livers were perfused using NMP. After one hour of stabilization, LiMAx testing was performed. Injury markers (ALT, AST, miR-122, FMN, and Suzuki-score) and lactate clearance were measured and related to LiMAx values. LiMAx values ranged between 111 and 1838 µg/kg/h, and performing consecutive LiMAx tests during longer NMP was feasible. No correlation was found between LiMAx value and miR-122 and FMN levels in the perfusate. However, a significant inverse correlation was found between LiMAx value and histological injury (Suzuki-score, R = − 0.874, P < 0.001), AST (R = − 0.812, P = 0.004) and ALT (R = − 0.687, P = 0.028). Furthermore, a significant correlation was found with lactate clearance (R = 0.683, P = 0.043). We demonstrate, as proof of principle, that liver function during NMP can be quantified using the LiMAx test, illustrating a positive correlation with traditional injury markers. This new breath-test application separates livers with adequate cytochromal liver function from inadequate ones and may support decision-making in the safe utilization of extended criteria donor grafts.
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